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GRAFT is an architectural firm located in Los Angeles, Berlin, and Beijing. Their collective professional experience encompasses a wide array of building types including Fine Arts, Educational, Institutional, Commercial and Residential facilities. The firm has won numerous awards in Europe as well as in the United States. GRAFT was established in 1998 in Los Angeles by Lars Krückeberg, Wolfram Putz and Thomas Willemeit and opened an office in Berlin in 2001. In 2003 GRAFT opened an office in Beijing with Gregor Hoheisel as partner for the asian market. In 2007 Alejandra Lillo became Partner for the office in Los Angeles. GRAFT was conceived as a ‘Label’ for Architecture, Urban Planning, Design, Music, and the “pursuit of happiness”. Since the firm was established, it has been commissioned to design and manage a wide range of projects in multiple disciplines and locations. With the core of the firm’s enterprises gravitating around the field of architecture and the built environment, GRAFT has always maintained an interest in crossing the boundaries between disciplines and “grafting” the creative potentials and methodologies of different realities. This is reflected in the firm’s expansion into the fields of exhibition design and product design, art installations, academic projects and “events” as well as in the variety of project locations in Germany, China, UAE, Russia, Georgia, in the U.S. and Mexico, to name a few.
PANTS ON FIRE?
(2011)
Grace Quiroga studied architecture at the University of Michigan and at the Vienna University of Technology. Her ongoing architectural projects include the design of a housing project in the Chinese province of Sichuan for a thousand families displaced by the earthquake of 2008. In addition, she is working on a doctoral dissertation titled “Rem Koolhaas and the architecture culture of the AA in the 1970’s”.
Albert Narath is a doctoral candidate in modern architectural history at Columbia University in New York and a Paul Mellon Pre-doctoral Fellow at the Center for Advanced Research in the Visual Arts at the National Gallery of Art in Washington, DC. He holds an MA degree from the Architectural Association in London. His dissertation concerns architectural and art historical debates surrounding the Neo-baroque at the end of the nineteenth century in Germany.
Nicole E. Stöcklmayr ist Post-Doc-Stipendiatin im Research-Fellow Programm „Werkzeuge des Entwerfens“ am Internationalen Kolleg für Kulturtechnikforschung und Medienphilosophie (IKKM) der Bauhaus-Universität Weimar. Stöcklmayr promovierte an der Universität für angewandte Kunst Wien an der sie auch Architektur in den Meisterklassen Hans Hollein, Greg Lynn sowie Zaha Hadid studierte. In ihrer von Gabriele Werner betreuten und von der Österreichischen Akademie der Wissenschaften geförderten Dissertation mit dem Titel „Das Architekturbild im digitalen Paradigmenwechsel“ untersuchte sie den Status des Bildes im digitalen Prozess des Architekturentwurfs. Veröffentlichungen: „Architektur ohne Maßstab. Digitale Visualisierungen im Entwurfsprozess“, in: Ingeborg Reichle, Steffen Siegel (Hg.), Maßlose Bilder. Visuelle Ästhetik der Transgression, München 2009, S. 279 – 294; „Das digitale Bild des Architekturentwurfs“, in: Gerald Bast, Florian Bettel, Barbara Hollendonner (Hg.), uni*vers. Junge Forschung in Wissenschaft und Kunst, Wien 2010; S. 59 – 69.
SENSUAL IS POLITICAL
(2011)
Daniela Brasil is currently a PhD candidate at the professorship of Spatial Planning and Research at Architecture Faculty of the Bauhaus-Universität Weimar, where she has also been teaching since 2007. Her seminars foster bodily experiments and critical thinking on “city’s sensuality”, where discussions on city marketing and affectivity are central. She was educated in architecture and urbanism in Brazil and Portugal and holds a Master of Fine Arts in Public Art and new artistic strategies. Idealizing and realizing artistic-oriented projects that intervene in relations between bodies and cities is her main concern since the mid-nineties; where she preferably works in transdisciplinary groups, as in “Lisbon Capital of Nothing: create, debate and intervene in public space, Marvila 2001”. Daniela currently runs the project “Baustelle M10 > gallery for contemporary experiments” within a collective of artists and students in Weimar.
ARCHITECTURE AND ATMOSPHERE
(2011)
Nathalie Bredella is an architect. She was educated at the TU Berlin and Cooper Union, New York. She received a PhD in Architectural Theory. She taught architectural design at the TU Berlin. She ist the author of Architekturen des Zuschauens. Imaginäre und reale Räume im Film (transcript-verlag). The work is based on an interdisciplinary approach incorporating architecture, film theory and philosophy. Her interests in architectural practice focus on the relationship between spatial strategies, film and media on an urban and architectural scale.
OÍDA OUK EIDÓS
(2011)
Ralf Hennig is a PhD-candidate at the chair of Theory and History of Modern Architecture at the Bauhaus-University Weimar. His prior research interests are focused on historical and current interaction between media, architecture and the city as well as the influence of the alliance of these entities on traditional principles of dwelling. In 2004-2005 he was responsible for the conception and constitution of the postgraduate Master’s degree programme MediaArchitecture at the Bauhaus-University Weimar. In 2007-2008 he worked there as a scientific associate at the chair of Sociology of Globalisation, involved in various activities such as the research project MEDIACITY.
Sandra Lippert-Vieira, 1971 in Lissabon, Portugal geboren, schloss 1995 ihr Architekturstudium an der Universidade Lusíada in Lissabon ab. Bis 2003 arbeitete sie als Freie Architektin in Lissabon und war Entwurfsassistentin an der Universidade Moderne und Universidade Lusófona in Lissabon bei Prof. em. Amâncio d’Alpoim Guedes, Lehrstuhl für Entwurf. Derzeit ist sie wissenschaftliche Mitarbeiterin im Fachgebiet Gebäudelehre bei Prof. Daniele Marques, Institut für Entwerfen, Kunst und Theorie, KIT – Karlsruher Institut für Technologie. Sie promovierte an der BTU Cottbus, Prof. Führ, zum Thema „Dissoziative Architektur. Zwischen Teufelskralle und Scheinriese. Wege zu einem weiteren Verständnis der Architektur des Expressionismus.“
Bisherige Veröffentlichungen:
„Wege zu einer Rezeptionsästhetik in der Architektur: das implizite Leben der gebauten Welt,“ in: Wolkenkuckucksheim (Heft 2/08); „Texte und Kontexte“ von Jürgen Habermas und „Martin Heidegger. Unterwegs zu seiner Biographie“ von Hugo Ott. Forschungsschwerpunkte: Expressionistische Architektur, Outsider Architektur, Architekturinterpretationsmethoden, Avantgarde und Postanarchismus.
FORM’S FALLOW FUNCTION
(2011)
Douglas Graf received an A.B. in architecture and urban planning from Princeton and a M.Arch. from Harvard and currently teaches courses in design and architectural theory at the Knowlton School of Architecture at the Ohio State University. His teaching career has included the Kentucky, Washington, and Yale, as well as positions in Britain, Germany, and Finland, where he first went on a Fulbright to study the work of Alvar Aalto. He has received five teaching awards. His interest in design theory has a primary focus on formal analysis, which is applied not only to architecture but also to urban form, landscape, photography, painting, product design, and graphics. One of his signature investigations has been into the structure and use of diagrams as tools for ‘close reading.’ Many of his investigations have explored ‘metaphoric time’ as a central design strategy. He has written about the idea of the ‘encyclopedic set’ as a persistent means of modeling complexity and the use of ‘fictive landscapes’ to derive narratives for the city. He currently divides his time between Columbus (the one in Ohio) and London (not the one in Ohio), where he has been researching the design strategies in English gardens and the formal structure of the pre-industrial village. He is one of the principals in Mid-Ohio Design, a firm of architects and urban designers whose work elides from the real to the academic and who have won a number of urban design competitions.
MODELLWECHSEL
(2011)
Wolfgang Pehnt lehrte Baugeschichte an der Ruhr-Universität Bochum. Er hat zahllose Arbeiten zur Architekturgeschichte der Moderne veröffentlicht und Monographien über Baumeister wie Gottfried Böhm, Hans Poelzig, Rudolf Schwarz und Karljosef Schattner geschrieben; er war Autor bei der Propyläen-Kunstgeschichte und Mitarbeiter von Fachzeitschriften, Katalogbüchern, Tageszeitungen und Rundfunkanstalten. Seine Bücher „Die Architektur des Expressionismus“ und „Deutsche Architektur seit 1900“ gelten als Standardwerke. Er wurde vielfach ausgezeichnet, zuletzt mit dem Deutschen Preis für Denkmalschutz (Karl Friedrich Schinkel-Ring).
Richard Shusterman received a B.A. and M.A. in Philosophy from the Hebrew University of Jerusalem, and completed his doctoral studies in Philosophy at Oxford University. In Israel he taught at the Hebrew University and the University of the Negev, and then moved to the United States, where he was Professor of Philosophy at Temple University, and chaired its department from 1998-2004. He then was awarded the Dorothy F. Schmidt Eminent Scholar Chair in the Humanities at Florida Atlantic University, where he also directs the Center for Body, Mind, and Culture. His authored books include Surface and Depth (2002); Performing Live (2000); Practicing Philosophy: Pragmatism and the Philosophical Life (1997); Sous l’interprétation (1994), Pragmatist Aesthetics: Living Beauty, Rethinking Art (1992, 2nd edition 2000); T.S. Eliot and the Philosophy of Criticism (1988); and The Object of Criticism (1984). His most recent book, Body Consciousness: A Philosophy of Mindfulness and Somaesthetics was published by Cambridge University Press. It provides the most detailed formulation of his project of somaesthetics.
Andreas Rumpfhuber is Architect and Researcher and currently based in Vienna, Austria. He studied architecture at University of Technology in Graz and the Bartlett School of Architecture in London. He is member of the research collective roundtable.kein.org at the Centre for Research Architecture at Goldsmiths College in London. He has taught and lectured at architecture schools in Europe and is a regular contributor to the Vienna street newspaper Augustin and architecture journals like derivé, UmBau, Monu, Arkitekten. In his office he is currently working on small scale projects.
EXPLAINING JUNKSPACE
(2011)
Dr. Silke Ötsch is currently working on a research project on the role of architects as intermediaries in financialization founded by the Austrian Research Found (FWF) at the Department of Sociology at the University of Innsbruck. She worked as scientific employee at the Institute of Construction and Design at the Innsbruck University, as lecturer at the Institute for Architecture Theory at the University of Innsbruck (Austria), in the architectural offices of Arets Architekten in Maastricht as well as Haid und Partner in Nürnberg and for Attac Germany. Silke Ötsch received her doctoral degree at the Bauhaus-University Weimar and studied architecture in Weimar and Paris. She published books in the field of architecture theory with the title “Stripping las Vegas” (with K. Jaschke) and “Überwältigen und Schmeicheln”, and articels in the review GAM and others, and published in the field of political economy, among others the book “Das Casino schließen” (together with T. Sauer and P. Wahl) on the financial crisis and “Räume der Offshore-Welt” (together with Celia Di Pauli), which is a publication on concrete spaces of tax havens and offshore centres in Europe and their implications. Her main research interest is globalization and financial architecture.
Hermann Czech studierte Architektur an der Technischen Hochschule und in der Meisterschule von Ernst Plischke an der Akademie der bildenden Künste in Wien. 1958 und 1959 war er Seminarteilnehmer bei Konrad Wachsmann an der Sommerakademie in Salzburg. An der Akademie für angewandte Kunst in Wien war er von 1974 bis 1980 Assistent bei Hans Hollein und Johannes Spalt, 1985/86 Gastprofessor an derselben Hochschule. 1988/89 und 1993/94 war er Gastprofessor an der Harvard University in Cambridge/USA, 2004-07 Gastprofessor an der ETH Zürich. Sein ungleichartiges architektonisches Werk umfasst Planungen, Wohn-, Schul- und Hotelbauten ebenso wie Interventionen in kleinem Maßstab und Ausstellungsgestaltungen. Seine Projekte haben starken Bezug zum Kontext und beinhalten bewusst die vorhandenen Widersprüche. Ab den 1970er Jahren (»Architektur ist Hintergrund«) wurde Hermann Czech zum Protagonisten einer neuen, »stillen« Architektur, die »nur spricht, wenn sie gefragt wird«. Er ist Autor zahlreicher kritischer und theoretischer Publikationen zur Architektur. In seiner Theorie spielen die Begriffe Umbau und Manierismus eine zentrale Rolle. Veröffentlichungen (Auswahl): ‚Zur Abwechslung. Ausgewählte Schriften zur Architektur. Wien‘, Wien 1996, ‚Das Looshaus‘, Wien 1976 (mit Wolfgang Mistelbauer), ‚Komfort – ein Gegenstand der Architekturtheorie?‘, in: werk,bauen+wohnen, Zürich, 3/2003, S. 10-15.
MAD is a Beijing-based architectural design studio. In their work, they are examining and developing a unique concept of futurism through current theoretical practice in architectural design, landscape design, and urban planning. In 2006, MAD was awarded the Architectural League Young Architects Forum Award. In the same year, MAD was shown at the ‘MAD in China’ exhibition in Venice during the Architecture Bienniale, and the ‘MAD Under Construction’ exhibition at the Tokyo Gallery in Beijing. MAD’s conceptual proposal, Super Star – A mobile China Town was exhibited in the Uneternal City of the 11th Architecture Biennale in Venice. Ma Yansong received his Master of Architecture from the Yale University School of Architecture in 2002. Prior to founding MAD in 2004, Mr. Ma worked as a project designer with Zaha Hadid Architects and Eisenman Architects. He also taught architecture at the Central Academy of Fine Arts in Beijing. In 2008, one of his built works, Hongluo Clubhouse, was nominated as one of the 100 designs by the London Design Museum. He was also nominated as one of the 20 most influential young architects today by ICON.
Professor Jane Rendell is Director of Architectural Research at the Bartlett, UCL. An architectural designer and historian, art critic and writer, her work has explored various interdisciplinary intersections: feminist theory and architectural history, ne art and architectural design, autobiographical writing and criticism. She is author of Site-Writing: The Architecture of Art Criticism (2010), Art and Architecture (2006), The Pursuit of Pleasure (2002) and co-editor of Pattern (2007), Critical Architecture (2007), Spatial Imagination (2005), The Unknown City (2001), Intersections (2000), Gender Space Architecture (1999) and Strangely Familiar (1995). Her talks and texts have been commissioned by artists such as Daniel Arsham and Bik Van Der Pol, and galleries, as the Baltic, the Hayward, Kunstmuseum Thon, the Serpentine, the Tate and the Whitechapel. She is on the Editorial Board for ARQ (Architectural Research Quarterly), Haecceity, The Happy Hypocrite, The Issues and the Journal of Visual Culture in Britain.
Martin Peschken studied History of Art and Literature in Berlin and Madrid. In 2005 he completed his doctoral studies in comparative literature at Freie Universität Berlin. He worked then as a curator of the gallery “Laden V-17” in Berlin. In 2005 he joined the project-team of International Building Exhibition “Stadtumbau 2010” in Saxony-Anhalt based at Stiftung Bauhaus Dessau, where he curated several exhibitions and urban projects. He currently works as Scientific Assistant at Technische Universität Braunschweig in the department of “History and Theory of Architecture and Urbanism”.
SYSWELD Forum 2011
(2011)
Am 25. und 26. Oktober 2011 trafen sich an der Bauhaus-Universität Weimar 70 nationale und internationale Fachleute aus Forschung und Praxis, um sich im Rahmen des vierten SYSWELD Forums über aktuelle Entwicklungen der numerischen Simulation auf dem Gebiet der Wärmebehandlung und des Schweißens auszutauschen. Die numerische Simulation im Bereich des Schweißens und der Wärmebehandlung hat sich in den letzten Jahren beachtlich weiterentwickelt und bietet ein zukunftsweisendes und innovatives Arbeitsfeld für Ingenieure.
PRÄ- UND POST-ARCHITEKTUR
(2011)
1988-1994 Redakteur bei Arch+. Gastprofessur an der TU Cottbus 2000–02. Initiator und Co-Leiter des Europäischen Forschungsprojekt Urban Catalyst 2001–03. Mitinitiator von ZwischenPalastNutzung und Künstlerischer Co-Leiter von Volkspalast 2004. Leitender Kurator des Projektes Schrumpfende Städte für die Kulturstiftung des Bundes 2002–08. Autor und Herausgeber mehrerer Bücher und Schriften, u.a. Wohltemperierte Architektur und Berlin_Stadt ohne Form. Seit Herbst 2006 Professor für Architekturtheorie und Entwerfen an der Universität Kassel, seit März 2009 Leiter der Stiftung Bauhaus Dessau.
FRAGEN ZU HANNES MEYER
(2011)
Otto Karl Werckmeister war, neben Forschungsaufträgen am Warburg Institute, London und dem Deutschen Archäologischen Institut, Professor für Kunstgeschichte an der UCLA und der Northwestern University in Evanstown/Illinois, sowie Gastprofessor an den Universitäten Marburg und Hamburg. Die Strategien von Künstlern des 20. Jahrhunderts auf dem Weg zum Ruhm hat er ebenso untersucht wie das Bildrepertoire frühmittelalterlicher Buchillustrationen oder der japanischen Manga-Comics. Walter Benjamins Forderung nach einer „Aktualität des Denkens“ hat ihm als Motto seiner Untersuchungen gedient. Zu seinen wichtigsten Veröffentlichungen gehören: Ende der Ästhetik (1971), Ideologie und Kunst bei Marx (1974), Versuche über Paul Klee (1981), The Making of Paul Klee‘s Career, 1914-1920 (1988), Zitadellenkultur. Die schöne Kunst des Untergangs in der Kultur der Achtziger Jahre (1989); Linke Ikonen: Benjamin, Eisenstein, Picasso - nach dem Fall des Kommunismus (1997), Der Medusa-Effekt - Politische Bildstrategien seit dem 11. September 2001 (2005).
THE HERPICH AFFAIR OF 1924
(2011)
Michele Stavagna is an architect and architectural historian, who lives and works in Berlin, and is the correspondent from Italy for the magazine “der architekt - BDA”. He was educated at the Università IUAV of Venice (Italy), holds a degree in architectural design and a PhD in history of architecture and urban design, and has taught Theory and History of Industrial Design at the Università degli Studi of Triest (Italy). Stavagna translated and edited the first Italian edition of “Die Baukunst der neuesten Zeit” by G. A. Platz. His research themes focus on the birth and affirmation of Modernism within the broader context of the mass public and economic development of the modern society.
CLOSING THE WORLD’S FACTORY
(2011)
Joshua Bolchover is an urban researcher, academic and architectural designer. He is an Assistant Professor at the University of Hong Kong, focusing on researching and designing buildings in rural China. In 2010 he exhibited Rural Urban Ecology at the Venice Biennale 2010. He has curated, designed and contributed to several international exhibitions including: Utopia Now: Opening the Closed Area, a research project on the Hong Kong and Shenzhen border at the Venice Biennale 2008; Get it Louder, a touring exhibition in China; Airspace: What Skyline does London want; Hydan; Can Buildings Curate and has exhibited at the HK-SZ Biennale. Joshua was a local curator for the Manchester-Liverpool section of Shrinking Cities between 2003 and 2005. He has collaborated with Raoul Bunschoten, Chora, researching strategic urban projects and has worked with Diller + Scofidio in New York. Joshua has previously taught architecture at the Chinese University of Hong Kong, London Metropolitan University, Cambridge University and the Architectural Association. He was educated at Cambridge University and at the Bartlett School of Architecture. John Lin is an architect based in Hong Kong and a graduate of The Cooper Union in New York City. His experimental constructions have been published in FRAME magazine (2003) and exhibited in the Kolonihaven (Architecture Park) at the Louisiana Museum of Modern Art in Copenhagen (2004) and the Venice Biennale (2008). Current projects include the design of several school buildings in China. He has taught at the Royal Danish Academy of Fine Arts, School of Architecture, and The Chinese University of Hong Kong and is currently an Assistant Professor at the University of Hong Kong.
WECHSELNDE ZUSCHREIBUNGEN
(2011)
Steffen de Rudder, Dr.-Ing., ist Architekt und wissenschaftlicher Mitarbeiter an der Bauhaus-Universität Weimar. Er lehrt städtebauliches Entwerfen und forscht zu Themen der Architektur- und Stadtbaugeschichte. 1996 Lehrbeauftragter am Kunsthistorischen Institut der Humboldt-Universität zu Berlin, 1990 bis 2001 selbstständiger Architekt in Potsdam und Berlin (Neubau, Sanierung, Denkmalpflege). Veröffentlichungen zur Bauhaus-Rezeption, zur amerikanischen Architekturgeschichte der Moderne und zur Stadtentwicklung in Berlin und in Thüringen. 2007 erschien: „Der Architekt Hugh Stubbins. Amerikanische Moderne der Fünfziger Jahre in Berlin“.
Yolanda Ortega Sanz is an architect and associate professor at Polytechnic School, Universitat de Girona, Catalonia, Spain; where she teaches architectural design. Ortega was educated at School of architecture in Barcelona and Arkitektskolen i Aarhus, Denmark. Later on, she received a grant to be a young researcher at Danmarks Kunstbibliotek, Copenhagen. Currently, she is PhD Candidate in the research group FORM where she develops her thesis entitled “Nordic assembly” focus on Modern Architecture in Nordic countries. Her research has been published and presented in several conferences as: 1st International Conference on contemporary architects: Jørn Utzon, Sevilla, Spain; 1st Conference on architectural competition, Nordic Symposium, KTH, Stockholm, Sweden; or Responsibilities and Opportunities in Architectural Conservation, CSAAR, Amman, Jordan.
DIE MODERNE ALS TRADITION
(2011)
Anne Schmedding ist als freie Kunst- und Architekturhistorikerin in Berlin tätig, unter anderem bei Urbanizers, Büro für städtische Konzepte. Von 2005 bis 2009 war sie wissenschaftliche Mitarbeiterin an der TU Braunschweig im Fachbereich Geschichte und Theorie der Architektur und Stadt. Sie ist Mitherausgeberin des Kataloges „Gesetz und Freiheit“ zu Leben und Werk des Architekten Friedrich Wilhelm Kraemers (Berlin 2007). Sie war von 1996–1999 Redakteurin der Zeitschrift Daidalos und ist Mitherausgeberin des Buches „Architektur in Berlin“ (Berlin 1999). Sie war wissenschaftliche Kuratorin und Mitarbeiterin der Ausstellung „Stadt der Architektur. Architektur der Stadt“, die im Jahr 2000 im Neuen Museum in Berlin zu sehen war. Momentaner Forschungsschwerpunkt ist Architektur und Kunst der westdeutschen Nachkriegszeit. Vor kurzem schloß sie ihre Dissertation über Dieter Oesterlen ab.
Dr. phil., seit 2001 Professorin für Geschichte und Theorie der Architektur und der Stadt; zuvor Professorin für Kunstgeschichte an der TU Graz; Gastprofessuren für Kunst-, Architektur- und Designgeschichte an der UdK Berlin, Universität Kassel, Oldenburg und Bonn; Studium der Kunstgeschichte, Soziologie, Psychologie und Philosophie. Karin Wilhelm ist Organisatorin mehrerer internationaler Ausstellungen zur modernen Architektur und zum Design (Berlin, London, Stock olm) und war wissenschaftlicher Beirat der Stiftung Bauhaus Dessau und des Deutschen Architekturmuseums (DAM). Zahlreiche Veröffentlichungen, zuletzt: Bauhaus Weimar 1919 –1924 (1996); Kunst als Revolte? Von der Fähigkeit der Künste, Nein zu sagen (1996); Visionen vom Glück – Visionen vom Untergang: Zeichen und Diskurse zur „schönen neuen Welt“ (1998); Sehen – Gehen – Denken: der Entwurf des Bauhausgebäudes, in: ‚Das Bauhausgebäude in Dessau 1926 –1999‘ (1998); City-Lights – Zentren, Peripherien, Regionen: interdisziplinäre Positionen für eine urbane Kultur (2002), Idea and form: Häuser von Szyszkowitz + Kowalski (2003); Formationen der Stadt. Camillo Sitte weitergelesen (2005).
Tobias Danielmeier teaches design at the Otago Polytechnic as well as at the University of Otago in Dunedin, New Zealand. He holds a Masters of Arts in Architecture from the Münster School of Architecture and is currently completing his PhD at the University of Otago. His research investigates the art, business and science of winery architecture and their interrelation with place and technology. Tobias Danielmeier’s practical experience includes projects for Reichardt Architekten, Essen, and Bolles+Wilson, Münster.
Tatjana Schneider is lecturer at the School of Architecture, University of Sheffield. She holds a PhD in architecture. She worked in architectural practice in Germany and the UK, and has taught, lectured and published widely (including ‘Flexible Housing’ with Jeremy Till). She was a member of the worker’s cooperative G.L.A.S. (Glasgow Letters on Architecture and Space), which undertook agit-prop works, educational workshops, community based design consultancy and produced the quarterly journal glaspaper. Her work focuses on the production and political economy of the built environment. Current work includes the research ‘Spatial Agency’.
GENUFLECTION AND EMPIRE
(2011)
Eymen Homsi has degrees in architecture from the Ohio State University and biology/botany from the University of Southern Colorado. He taught design and theory at the Ohio State University (1991–99), worked at the Atelier Jose Oubrerie (1991–1995), and was Director of Design at the Columbus Neighborhood Design Centre (1998–99), where he designed the Salvation Army Transitional Housing, Friends of the Homeless Dormitory, and other public projects. He established Studio Noni in Helsinki (2000–04) for experimental projects, speculative works, competitions. He was coordinator of Habitation Studio at the Chinese University of Hong Kong (2004–09). He returned to Istanbul in 2009 after an absence of thirty five years to teach studio at Mimar Sinan University of Fine Arts (2009–10). Currently he teaches studio at Istanbul Technical University, and theory at Kültür University. His research concerns the relationship between rites of worship in Islam and the space of the mosque.
HOW CRITICAL IS CRITICALITY?
(2011)
Rixt Hoekstra is an architectural historian and a Wissenschaftliche Mitarbeiterin at the Leopold Franzens University of Innsbruck, where she teaches theory and history of architecture. Hoekstra studied architectural history in Groningen, the Netherlands, and received her PhD in architectural history in 2005. Her publications include: Building versus Bildung, Manfredo Tafuri and the construction of a historical discipline (2005) and Lost in Translation? Tafuri on Germany, Tafuri in Germany, a history of reception (2008). Currently, her research interests focus on the status of criticality in architecture in relationship to the legacy of the Venice School and on genderstudies in architecture.
Due to the complex interactions between the ground, the driving machine, the lining tube and the built environment, the accurate assignment of in-situ system parameters for numerical simulation in mechanized tunneling is always subject to tremendous difficulties. However, the more accurate these parameters are, the more applicable the responses gained from computations will be. In particular, if the entire length of the tunnel lining is examined, then, the appropriate selection of various kinds of ground parameters is accountable for the success of a tunnel project and, more importantly, will prevent potential casualties. In this context, methods of system identification for the adaptation of numerical simulation of ground models are presented. Hereby, both deterministic and probabilistic approaches are considered for typical scenarios representing notable variations or changes in the ground model.
The topic of structural robustness is covered extensively in current literature in structural engineering. A few evaluation methods already exist. Since these methods are based on different evaluation approaches, the comparison is difficult. But all the approaches have one in common, they need a structural model which represents the structure to be evaluated. As the structural model is the basis of the robustness evaluation, there is the question if the quality of the chosen structural model is influencing the estimation of the structural robustness index. This paper shows what robustness in structural engineering means and gives an overview of existing assessment methods. One is the reliability based robustness index, which uses the reliability indices of a intact and a damaged structure. The second one is the risk based robustness index, which estimates the structural robustness by the usage of direct and indirect risk. The paper describes how these approaches for the evaluation of structural robustness works and which parameters will be used. Since both approaches needs a structural model for the estimation of the structural behavior and the probability of failure, it is necessary to think about the quality of the chosen structural model. Nevertheless, the chosen model has to represent the structure, the input factors and reflect the damages which occur. On the example of two different model qualities, it will be shown, that the model choice is really influencing the quality of the robustness index.
A numerical analysis of the mode of deformation of the main load-bearing components of a typical frame sloping shaft headgear was performed. The analysis was done by a design model consisting of plane and solid finite elements, which were modeled in the program «LIRA». Due to the numerical results, the regularities of local stress distribution under a guide pulley bearing were revealed and parameters of a plane stress under both emergency and normal working loads were determined. In the numerical simulation, the guidelines to improve the construction of the joints of guide pulleys resting on sub-pulley frame-type structures were established. Overall, the results obtained are the basis for improving the engineering procedures of designing steel structures of shaft sloping headgear.
Many structures in different engineering applications suffer from cracking. In order to make reliable prognosis about the serviceability of those structures it is of utmost importance to identify cracks as precisely as possible by non-destructive testing. A novel approach (XIGA), which combines the Isogeometric Analysis (IGA) and the Extended Finite Element Method (XFEM) is used for the forward problem, namely the analysis of a cracked material, see [1]. Applying the NURBS (Non-Uniform Rational B-Spline) based approach from IGA together with the XFEM allows to describe effectively arbitrarily shaped cracks and avoids the necessity of remeshing during the crack identification problem. We want to exploit these advantages for the inverse problem of detecting existing cracks by non-destructive testing, see e.g. [2]. The quality of the reconstructed cracks however depends on two major issues, namely the quality of the measured data (measurement error) and the discretization of the crack model. The first one will be taken into account by applying regularizing methods with a posteriori stopping criteria. The second one is critical in the sense that too few degrees of freedom, i.e. the number of control points of the NURBS, do not allow for a precise description of the crack. An increased number of control points, however, increases the number of unknowns in the inverse analysis and intensifies the ill-posedness. The trade-off between accuracy and stability is aimed to be found by applying an inverse multilevel algorithm [3, 4] where the identification is started with short knot vectors which successively will be enlarged during the identification process.
The process of analysis and design in structural engineering requires the consideration of different partial models, for example loading, structural materials, structural elements, and analysis types. The various partial models are combined by coupling several of their components. Due to the large number of available partial models describing similar phenomena, many different model combinations are possible to simulate the same aspects of a structure. The challenging task of an engineer is to select a model combination that ensures a sufficient, reliable prognosis. In order to achieve this reliable prognosis of the overall structural behavior, a high individual quality of the partial models and an adequate coupling of the partial models is required. Several methodologies have been proposed to evaluate the quality of partial models for their intended application, but a detailed study of the coupling quality is still lacking. This paper proposes a new approach to assess the coupling quality of partial models in a quantitative manner. The approach is based on the consistency of the coupled data and applies for uni- and bidirectional coupled partial models. Furthermore, the influence of the coupling quality on the output quantities of the partial models is considered. The functionality of the algorithm and the effect of the coupling quality are demonstrated using an example of coupled partial models in structural engineering.
THE INFLUENCE OF THE LOCAL CONCAVITY ON THE FUNCTIONING OF BEARING SHELL OF HIGH-RISE CONSTRUCTION
(2012)
Areas with various defects and damages, which reduce carrying capacity, were examined in a study of metal chimneys. In this work, the influence of the local dimples on the function of metal chimneys was considered. Modeling tasks were completed in the software packages LIRA and ANSYS. Parameters were identified, which characterize the local dimples, and a numerical study of the influence of local dimples on the stress-strain state of shells of metal chimneys was conducted. A distribution field of circular and meridional tension was analyzed in a researched area. Zones of influence of dimples on the bearing cover of metal chimneys were investigated. The bearing capacities of high-rise structures with various dimple geometries and various cover parameters were determined with respect to specified areas of the trunk. Dependent relationships are represented graphically for the decrease in bearing capacity of a cover with respect to dimples. Diameter and thickness of covers of metal chimneys were constructed according to the resulting data.
The analysis of the response of complex structural systems requires the description of the material constitutive relations by means of an appropriate material model. The level of abstraction of such model may strongly affect the quality of the prognosis of the whole structure. In context to this fact, it is necessary to describe the material in a convenient sense as exact but as simple as possible. All material phenomena of crystalline materials e.g. steel, affecting the behavior of the structure, rely on physical effects which are interacting over spatial scales from subatomic to macroscopic range. Nevertheless, if the material is microscopically heterogenic, it might be appropriate to use phenomenological models for the purpose of civil engineering. Although constantly applied, these models are insufficient for steel materials with microscopic characteristics such as texture, typically occurring in hot rolled steel members or heat affected zones of welded joints. Hence, texture is manifested in crystalline materials as a regular crystallographic structure and crystallite orientation, influencing macroscopic material properties. The analysis of structural response of material with texture (e.g. rolled steel or heat affected zone of a welded joint) obliges the extension of the phenomenological material description of macroscopic scale by means of microscopic information. This paper introduces an enrichment approach for material models based on a hierarchical multiscale methodology. This has been done by describing the grain texture on a mesoscopic scale and coupling it with macroscopic constitutive relations by means of homogenization. Due to a variety of available homogenization methods, the question of an assessment of coupling quality arises. The applicability of the method and the effect of the coupling method on the reliability of the response are presented on an example.
BAUHAUS ISOMETRY AND FIELDS
(2012)
While integration increases by networking, segregation strides ahead too. Most of us fixate our mind on special topics. Yet we are relying on our intuition too. We are sometimes waiting for the inflow of new ideas or valuable information that we hold in high esteem, although we are not entirely conscious of its origin. We may even say the most precious intuitions are rooting in deep subconscious, collective layers of the mind. Take as a simple example the emergence of orientation in paleolithic events and its relation to the dihedral symmetry of the compass. Consider also the extension of this algebraic matter into the operational structures of the mind on the one hand and into the algebra of geometry, Clifford algebra as we use to call it today, on the other. Culture and mind, and even the individual act of creation may be connected with transient events that are subconscious and inaccessible to cognition in principle. Other events causative for our work may be merely invisible too us, though in principle they should turn out attainable. In this case we are just ignorant of the whole creative process. Sometimes we begin to use unusual tools or turn into handicraft enthusiasts. Then our small institutes turn into workshops and factories. All this is indeed joining with the Bauhaus and its spirit. We shall go together into this, and we shall present a record of this session.
Electromagnetic wave propagation is currently present in the vast majority of situations which occur in veryday life, whether in mobile communications, DTV, satellite tracking, broadcasting, etc. Because of this the study of increasingly complex means of propagation of lectromagnetic waves has become necessary in order to optimize resources and increase the capabilities of the devices as required by the growing demand for such services.
Within the electromagnetic wave propagation different parameters are considered that characterize it under various circumstances and of particular importance are the reflectance and transmittance. There are several methods or the analysis of the reflectance and transmittance such as the method of approximation by boundary condition, the plane wave expansion method (PWE), etc., but this work focuses on the WKB and SPPS methods.
The implementation of the WKB method is relatively simple but is found to be relatively efficient only when working at high frequencies. The SPPS method (Spectral Parameter Powers Series) based on the theory of pseudoanalytic functions, is used to solve this problem through a new representation for solutions of Sturm Liouville equations and has recently proven to be a powerful tool to solve different boundary value and eigenvalue problems. Moreover, it has a very suitable structure for numerical implementation, which in this case took place in the Matlab software for the valuation of both conventional and turning points profiles.
The comparison between the two methods allows us to obtain valuable information about their perfor mance which is useful for determining the validity and propriety of their application for solving problems where these parameters are calculated in real life applications.
Long-span cable supported bridges are prone to aerodynamic instabilities caused by wind and this phenomenon is usually a major design criterion. If the wind speed exceeds the critical flutter speed of the bridge, this constitutes an Ultimate Limit State. The prediction of the flutter boundary therefore requires accurate and robust models. This paper aims at studying various combinations of models to predict the flutter phenomenon.
Since flutter is a coupling of aerodynamic forcing with a structural dynamics problem, different types and classes of models can be combined to study the interaction. Here, both numerical approaches and analytical models are utilised and coupled in different ways to assess the prediction quality of the hybrid model. Models for aerodynamic forces employed are the analytical Theodorsen expressions for the motion-enduced aerodynamic forces of a flat plate and Scanlan derivatives as a Meta model. Further, Computational Fluid Dynamics (CFD) simulations using the Vortex Particle Method (VPM) were used to cover numerical models.
The structural representations were dimensionally reduced to two degree of freedom section models calibrated from global models as well as a fully three-dimensional Finite Element (FE) model. A two degree of freedom system was analysed analytically as well as numerically.
Generally, all models were able to predict the flutter phenomenon and relatively close agreement was found for the particular bridge. In conclusion, the model choice for a given practical analysis scenario will be discussed in the context of the analysis findings.
We study the Weinstein equation u on the upper half space R3+. The Weinstein equation is connected to the axially symmetric potentials. We compute solutions of the Weinstein equation depending on the hyperbolic distance and x2. These results imply the explicit mean value properties. We also compute the fundamental solution. The main tools are the hyperbolic metric and its invariance properties.
The present research analyses the error on prediction obtained under different data availability scenarios to determine which measurements contribute to an improvement of model prognosis and which not. A fully coupled 2D hydromechanical model of a water retaining dam is taken as an example. Here, the mean effective stress in the porous skeleton is reduced due to an increase in pore water pressure under drawdown conditions. Relevant model parameters are ranked by scaled sensitivities, Particle Swarm Optimization is applied to determine the optimal parameter values and model validation is performed to determine the magnitude of error forecast. We compare the predictions of the optimized models with results from a forward run of the reference model to obtain actual prediction errors.
The analyses presented here were performed to 31 data sets of 100 observations of varying data types. Calibrating with multiple information types instead of only one sort, brings better calibration results and improvement in model prognosis. However, when using several types of information the number of observations have to be increased to be able to cover a representative part of the model domain; otherwise a compromise between data availability and domain
coverage prove best. Which type of information for calibration contributes to the best prognoses, could not be determined in advance. For the error in model prognosis does not depends on the error in calibration, but on the parameter error, which unfortunately can not be determined in reality since we do not know its real value. Excellent calibration fits with parameters’ values near the limits of reasonable physical values, provided the highest prognosis errors. While models which included excess pore pressure values for calibration provided the best prognosis, independent of the calibration fit.
Numerical simulations in the general field of civil engineering are common for the design process of structures and/or the assessment of existing buildings. The behaviour of these structures is analytically unknown and is approximated with numerical simulation methods like the Finite Element Method (FEM). Therefore the real structure is transferred into a global model (GM, e.g. concrete bridge) with a wide range of sub models (partial models PM, e.g. material modelling, creep). These partial models are coupled together to predict the behaviour of the observed structure (GM) under different conditions. The engineer needs to decide which models are suitable for computing realistically and efficiently the physical processes determining the structural behaviour. Theoretical knowledge along with the experience from prior design processes will influence this model selection decision. It is thus often a qualitative selection of different models. The goal of this paper is to present a quantitative evaluation of the global model quality according to the simulation of a bridge subject to direct loading (dead load, traffic) and indirect loading (temperature), which induce restraint effects. The model quality can be separately investigated for each partial model and also for the coupled partial models in a global structural model. Probabilistic simulations are necessary for the evaluation of these model qualities by using Uncertainty and Sensitivity Analysis. The method is applied to the simulation of a semi-integral concrete bridge with a monolithic connection between the superstructure and the piers, and elastomeric bearings at the abutments. The results show that the evaluation of global model quality is strongly dependent on the sensitivity of the considered partial models and their related quantitative prediction quality. This method is not only a relative comparison between different models, but also a quantitative representation of model quality using probabilistic simulation methods, which can support the process of model selection for numerical simulations in research and practice.
Safety operation of important civil structures such as bridges can be estimated by using fracture analysis. Since the analytical methods are not capable of solving many complicated engineering problems, numerical methods have been increasingly adopted. In this paper, a part of isotropic material which contains a crack is considered as a partial model and the proposed model quality is evaluated. EXtended IsoGeometric Analysis (XIGA) is a new developed numerical approach [1, 2] which benefits from advantages of its origins: eXtended Finite Element Method (XFEM) and IsoGeometric Analysis (IGA). It is capable of simulating crack propagation problems with no remeshing necessity and capturing singular field at the crack tip by using the crack tip enrichment functions. Also, exact representation of geometry is possible using only few elements. XIGA has also been successfully applied for fracture analysis of cracked orthotropic bodies [3] and for simulation of curved cracks [4]. XIGA applies NURBS functions for both geometry description and solution field approximation. The drawback of NURBS functions is that local refinement cannot be defined regarding that it is based on tensorproduct constructs unless multiple patches are used which has also some limitations. In this contribution, the XIGA is further developed to make the local refinement feasible by using Tspline basis functions. Adopting a recovery based error estimator in the proposed approach for evaluation of the model quality and performing the adaptive processes is in progress. Finally, some numerical examples with available analytical solutions are investigated by the developed scheme.
This paper presents a robust model updating strategy for system identification of wind turbines. To control the updating parameters and to avoid ill-conditioning, the global sensitivity analysis using the elementary effects method is conducted. The formulation of the objective function is based on M¨uller-Slany’s strategy for multi-criteria functions. As a simulationbased optimization, a simulation adapter is developed to interface the simulation software ANSYS and the locally developed optimization software MOPACK. Model updating is firstly tested on the beam model of the rotor blade. The defect between the numerical model and the reference has been markedly reduced by the process of model updating. The effect of model updating becomes more pronounced in the comparison of the measured and the numerical properties of the wind turbine model. The deviations of the frequencies of the updated model are rather small. The complete comparison including the free vibration modes by the modal assurance criteria shows the excellent coincidence of the modal parameters of the updated model with the ones from the measurements. By successful implementation of the model validation via model updating, the applicability and effectiveness of the solution concept has been demonstrated.
MODEL DESCRIBING STATIC AND DYNAMIC DISPLACEMENTS OF SILOS WALL DURING THE FLOW OF LOOSE MATERIAL
(2012)
Correct evaluation of wall displacements is a key matter when designing silos. This issue is important from both the standpoint of design engineer (load-bearing capacity of structures) and end-consumer (durability of structures). Commonplace methods of silo design mainly focus on satisfying limit states of load-bearing capacity. Current standards fail to specify methods of dynamic displacements analysis. Measurements of stressacting on silo walls prove that the actual stress is sum of static and dynamic stresses. Janssen came up with differential equation describing state of static equilibrium in cross-section of a silo. By solving the equation static stress of granular solid on silo walls can be determined. Equations of motion were determined from equilibrium equations of feature objects. General solution, describing dynamic stresses was presented as parametric model. This paper presents particular integrals of differential equation, which enable analysing displacements and vibrations for different rigidities of silo walls, types of granular solid and its flow rate.
Bridge vibration due to traffic loading has been subject of extensive research in the last decades. Such studies are concerned with deriving solutions for the bridge-vehicle interaction (BVI) and analyzing the dynamic responses considering randomness of the coupled model’s (BVI) input parameters and randomness of road unevenness. This study goes further to examine the effects of such randomness of input parameters and processes on the variance of dynamic responses in quantitative measures. The input parameters examined in the sensitivity analysis are, stiffness and damping of vehicle’s suspension system, axle spacing, and stiffness and damping of bridge. This study also examines the effects of the initial excitation of a vehicle on the influences of the considered input parameters. Variance based sensitivity analysis is often applied to deterministic models. However, the models for the dynamic problem is a stochastic one due to the simulations of the random processes. Thus, a setting using a joint meta-model; one for the mean response and other for the dispersion of the response is developed. The joint model is developed within the framework of Generalized Linear Models (GLM). An enhancement of the GLM procedure is suggested and tested; this enhancement incorporates Moving Least Squares (MLS) approximation algorithms in the fitting of the mean component of the joint model. The sensitivity analysis is then performed on the joint-model developed for the dynamic responses caused by BVI.
In this paper we review two distint complete orthogonal systems of monogenic polynomials over 3D prolate spheroids. The underlying functions take on either values in the reduced and full quaternions (identified, respectively, with R3 and R4), and are generally assumed to be nullsolutions of the well known Riesz and Moisil Théodoresco systems in R3. This will be done in the spaces of square integrable functions over R and H. The representations of these polynomials are explicitly given. Additionally, we show that these polynomial functions play an important role in defining the Szegö kernel function over the surface of 3D spheroids. As a concrete application, we prove the explicit expression of the monogenic Szegö kernel function over 3D prolate spheroids.
DISCRETE CRACK MODEL OF BORCZ FOR CALCULATING THE DEFLECTIONS OF BENDING REINFORCED CONCRETE BEAM
(2012)
In the design of the reinforced concrete beams loaded by the bending moment, it is assumed that the structure can be used at a level of load, that there are local discontinuities - cracks. Designing the element demands checking two limit states of construction, load capacity and usability. Limit states usability include also the deflection of the element. Deflections in the reinforced concrete beams with cracks are based on actual rigidity of the element. After cracking there is a local change in rigidity of the beam. The rigidity is variable in the element’s length and due to the heterogeneous structure of concrete, it is not possible to clearly describe those changes. Most standards of testing methods tend to simplify the calculations and take the average value of the beam’s rigidity on its entire length. The rigidity depends on the level of the maximal load of the beam. Experimental researches verify the value by inserting the coefficients into the formulas used in the theory of elasticity. The researches describe the changes in rigidity in the beam’s length more precisely. The authors take into consideration the change of rigidity, depending on the level of maximum load (continuum models), or localize the changes in rigidity in the area of the cracks (discrete models). This paper presents one of the discrete models. It is distinguished by the fact that the left side of the differential equation, that depends on the rigidity, is constant, and all effects associated with the scratches are taken as the external load and placed on the right side of the equation. This allows to generalize the description. The paper presents a particular integral of the differential equation, which allow analyzing the displacement and vibration for different rigidity of the silo’s walls, the flow rate and type of the flowing material.
In this paper experimental studies and numerical analysis carried out on reinforced concrete beam are partially reported. They aimed to apply the rigid finite element method to calculations for reinforced concrete beams using discrete crack model. Hence rotational ductility resulting from crack occurrence had to be determined. A relationship for calculating it in static equilibrium was proposed. Laboratory experiments proved that dynamic ductility is considerably smaller. Therefore scaling of the empirical parameter was carried out. Consequently a formula for its value depending on reinforcement ratio was obtained.
The Bernstein polynomials are used for important applications in many branches of Mathematics and the other sciences, for instance, approximation theory, probability theory, statistic theory, num- ber theory, the solution of the di¤erential equations, numerical analysis, constructing Bezier curves, q-calculus, operator theory and applications in computer graphics. The Bernstein polynomials are used to construct Bezier curves. Bezier was an engineer with the Renault car company and set out in the early 1960’s to develop a curve formulation which would lend itself to shape design. Engineers may …nd it most understandable to think of Bezier curves in terms of the center of mass of a set of point masses. Therefore, in this paper, we study on generating functions and functional equations for these polynomials. By applying these functions, we investigate interpolation function and many properties of these polynomials.
A concept of non-commutative Galois extension is introduced and binary and ternary extensions are chosen. Non-commutative Galois extensions of Nonion algebra and su(3) are constructed. Then ternary and binary Clifford analysis are introduced for non-commutative Galois extensions and the corresponding Dirac operators are associated.
New foundations for geometric algebra are proposed based upon the existing isomorphisms between geometric and matrix algebras. Each geometric algebra always has a faithful real matrix representation with a periodicity of 8. On the other hand, each matrix algebra is always embedded in a geometric algebra of a convenient dimension. The geometric product is also isomorphic to the matrix product, and many vector transformations such as rotations, axial symmetries and Lorentz transformations can be written in a form isomorphic to a similarity transformation of matrices. We collect the idea that Dirac applied to develop the relativistic electron equation when he took a basis of matrices for the geometric algebra instead of a basis of geometric vectors. Of course, this way of understanding the geometric algebra requires new definitions: the geometric vector space is defined as the algebraic subspace that generates the rest of the matrix algebra by addition and multiplication; isometries are simply defined as the similarity transformations of matrices as shown above, and finally the norm of any element of the geometric algebra is defined as the nth root of the determinant of its representative matrix of order n×n. The main idea of this proposal is an arithmetic point of view consisting of reversing the roles of matrix and geometric algebras in the sense that geometric algebra is a way of accessing, working and understanding the most fundamental conception of matrix algebra as the algebra of transformations of multilinear quantities.
We briefly review and use the recent comprehensive research on the manifolds of square roots of −1 in real Clifford geometric algebras Cl(p,q) in order to construct the Clifford Fourier transform. Basically in the kernel of the complex Fourier transform the complex imaginary unit j is replaced by a square root of −1 in Cl(p,q). The Clifford Fourier transform (CFT) thus obtained generalizes previously known and applied CFTs, which replaced the complex imaginary unit j only by blades (usually pseudoscalars) squaring to −1. A major advantage of real Clifford algebra CFTs is their completely real geometric interpretation. We study (left and right) linearity of the CFT for constant multivector coefficients in Cl(p,q), translation (x-shift) and modulation (w -shift) properties, and signal dilations. We show an inversion theorem. We establish the CFT of vector differentials, partial derivatives, vector derivatives and spatial moments of the signal. We also derive Plancherel and Parseval identities as well as a general convolution theorem.
This paper presents a methodology for uncertainty quantification in cyclic creep analysis. Several models- , namely BP model, Whaley and Neville model, modified MC90 for cyclic loading and modified Hyperbolic function for cyclic loading are used for uncertainty quantification. Three types of uncertainty are included in Uncertainty Quantification (UQ): (i) natural variability in loading and materials properties; (ii) data uncertainty due to measurement errors; and (iii) modelling uncertainty and errors during cyclic creep analysis. Due to the consideration of all type of uncertainties, a measure for the total variation of the model response is achieved. The study finds that the BP, modified Hyperbolic and modified MC90 are best performing models for cyclic creep prediction in that order. Further, global Sensitivity Analysis (SA) considering the uncorrelated and correlated parameters is used to quantify the contribution of each source of uncertainty to the overall prediction uncertainty and to identifying the important parameters. The error in determining the input quantities and model itself can produce significant changes in creep prediction values. The variability influence of input random quantities on the cyclic creep was studied by means of the stochastic uncertainty and sensitivity analysis namely the Gartner et al. method and Saltelli et al. method. All input imperfections were considered to be random quantities. The Latin Hypercube Sampling (LHS) numerical simulation method (Monte Carlo type method) was used. It has been found by the stochastic sensitivity analysis that the cyclic creep deformation variability is most sensitive to the Elastic modulus of concrete, compressive strength, mean stress, cyclic stress amplitude, number of cycle, in that order.
The 19th International Conference on the Applications of Computer Science and Mathematics in Architecture and Civil Engineering will be held at the Bauhaus University Weimar from 4th till 6th July 2012. Architects, computer scientists, mathematicians, and engineers from all over the world will meet in Weimar for an interdisciplinary exchange of experiences, to report on their results in research, development and practice and to discuss. The conference covers a broad range of research areas: numerical analysis, function theoretic methods, partial differential equations, continuum mechanics, engineering applications, coupled problems, computer sciences, and related topics. Several plenary lectures in aforementioned areas will take place during the conference.
We invite architects, engineers, designers, computer scientists, mathematicians, planners, project managers, and software developers from business, science and research to participate in the conference!
Monogenic functions play a role in quaternion analysis similarly to that of holomorphic functions in complex analysis. A holomorphic function with nonvanishing complex derivative is a conformal mapping. It is well-known that in Rn+1, n ≥ 2 the set of conformal mappings is restricted to the set of Möbius transformations only and that the Möbius transformations are not monogenic. The paper deals with a locally geometric mapping property of a subset of monogenic functions with nonvanishing hypercomplex derivatives (named M-conformal mappings). It is proved that M-conformal mappings orthogonal to all monogenic constants admit a certain change of solid angles and vice versa, that change can characterize such mappings. In addition, we determine planes in which those mappings behave like conformal mappings in the complex plane.
The aim of this paper we discuss explicit series constructions for the fundamental solution of the Helmholtz operator on some important examples non-orientable conformally at manifolds. In the context of this paper we focus on higher dimensional generalizations of the Klein bottle which in turn generalize higher dimensional Möbius strips that we discussed in preceding works. We discuss some basic properties of pinor valued solutions to the Helmholtz equation on these manifolds.
This paper is focused on the first numerical tests for coupling between analytical solution and finite element method on the example of one problem of fracture mechanics. The calculations were done according to ideas proposed in [1]. The analytical solutions are constructed by using an orthogonal basis of holomorphic and anti-holomorphic functions. For coupling with finite element method the special elements are constructed by using the trigonometric interpolation theorem.
The aim of our contribution is to clarify the relation between totally regular variables and Appell sequences of hypercomplex holomorphic polynomials (sometimes simply called monogenic power-like functions) in Hypercomplex Function Theory. After their introduction in 2006 by two of the authors of this note on the occasion of the 17th IKM, the latter have been subject of investigations by different authors with different methods and in various contexts. The former concept, introduced by R. Delanghe in 1970 and later also studied by K. Gürlebeck in 1982 for the case of quaternions, has some obvious relationship with the latter, since it describes a set of linear hypercomplex holomorphic functions all power of which are also hypercomplex holomorphic. Due to the non-commutative nature of the underlying Clifford algebra, being totally regular variables or Appell sequences are not trivial properties as it is for the integer powers of the complex variable z=x+ iy. Simple examples show also, that not every totally regular variable and its powers form an Appell sequence and vice versa. Under some very natural normalization condition the set of all para-vector valued totally regular variables which are also Appell sequences will completely be characterized. In some sense the result can also be considered as an answer to a remark of K. Habetha in chapter 16: Function theory in algebras of the collection Complex analysis. Methods, trends, and applications, Akademie-Verlag Berlin, (Eds. E. Lanckau and W. Tutschke) 225-237 (1983) on the use of exact copies of several complex variables for the power series representation of any hypercomplex holomorphic function.
In this paper, wavelet energy damage indicator is used in response surface methodology to identify the damage in simulated filler beam railway bridge. The approximate model is addressed to include the operational and surrounding condition in the assessment. The procedure is split into two stages, the training and detecting phase. During training phase, a so-called response surface is built from training data using polynomial regression and radial basis function approximation approaches. The response surface is used to detect the damage in structure during detection phase. The results show that the response surface model is able to detect moderate damage in one of bridge supports while the temperatures and train velocities are varied.
Civil engineers take advantage of models to design reliable structures. In order to fulfill the design goal with a certain amount of confidence, the utilized models should be able to predict the probable structural behavior under the expected loading schemes. Therefore, a major challenge is to find models which provide less uncertain and more robust responses. The problem gets even twofold when the model to be studied is a global model comprised of different interacting partial models. This study aims at model quality evaluation of global models with a focus on frame-wall systems as the case study. The paper, presents the results of the first step taken toward accomplishing this goal. To start the model quality evaluation of the global frame-wall system, the main element (i.e. the wall) was studied through nonlinear static and dynamic analysis using two different modeling approaches. The two selected models included the fiber section model and the Multiple-Vertical-Line-Element-Model (MVLEM). The influence of the wall aspect ratio (H=L) and the axial load on the response of the models was studied. The results from nonlinear static and dynamic analysis of both models are presented and compared. The models resulted in quite different responses in the range of low aspect ratio walls under large axial loads due to different contribution of the shear deformations to the top displacement. In the studied cases, the results implied that careful attention should be paid to the model quality evaluation of the wall models specifically when they are supposed to be coupled to other partial models such as a moment frame or a soil-footing substructure which their response is sensitive to shear deformations. In this case, even a high quality wall model would not result in a high quality coupled system since it fails to interact properly with the rest of the system.
The aim of this study is to show an application of model robustness measures for soilstructure interaction (henceforth written as SSI) models. Model robustness defines a measure for the ability of a model to provide useful model answers for input parameters which typically have a wide range in geotechnical engineering. The calculation of SSI is a major problem in geotechnical engineering. Several different models exist for the estimation of SSI. These can be separated into analytical, semi-analytical and numerical methods. This paper focuses on the numerical models of SSI specific macro-element type models and more advanced finite element method models using contact description as continuum or interface elements. A brief description of the models used is given in the paper. Following this description, the applied SSI problem is introduced. The observed event is a static loaded shallow foundation with an inclined load. The different partial models to consider the SSI effects are assessed using different robustness measures during numerical application. The paper shows the investigation of the capability to use these measures for the assessment of the model quality of SSI partial models. A variance based robustness and a mathematical robustness approaches are applied. These different robustness measures are used in a framework which allows also the investigation of computational time consuming models. Finally the result shows that the concept of using robustness approaches combined with other model–quality indicators (e.g. model sensitivity or model reliability) can lead to unique model–quality assessment for SSI models.
Non-destructive techniques for damage detection became the focus of engineering interests in the last few years. However, applying these techniques to large complex structures like civil engineering buildings still has some limitations since these types of structures are
unique and the methodologies often need a large number of specimens for reliable results. For this reason, cost and time can greatly influence the final results.
Model Assisted Probability Of Detection (MAPOD) has taken its place among the ranks of damage identification techniques, especially with advances in computer capacity and modeling tools. Nevertheless, the essential condition for a successful MAPOD is having a reliable model in advance. This condition is opening the door for model assessment and model quality problems. In this work, an approach is proposed that uses Partial Models (PM) to compute the Probability Of damage Detection (POD). A simply supported beam, that can be structurally modified and
tested under laboratory conditions, is taken as an example. The study includes both experimental and numerical investigations, the application of vibration-based damage detection approaches and a comparison of the results obtained based on tests and simulations.
Eventually, a proposal for a methodology to assess the reliability and the robustness of the models is given.
It is well known that complex quaternion analysis plays an important role in the study of higher order boundary value problems of mathematical physics. Following the ideas given for real quaternion analysis, the paper deals with certain orthogonal decompositions of the complex quaternion Hilbert space into its subspaces of null solutions of Dirac type operator with an arbitrary complex potential. We then apply them to consider related boundary value problems, and to prove the existence and uniqueness as well as the explicit representation formulae of the underlying solutions.
Der Nachbehandlung eines Fahrbahndeckenbetons kommt zum Erzielen eines hohen Frost-Tausalz-Widerstandes der fertigen Betondecke eine besondere Bedeutung zu. Bei der Waschbetonbauweise erfolgt die Nachbehandlung in mehreren Schritten. Eine erste Nachbehandlung gewährleistet den Verdunstungsschutz des Betons bis zum Zeitpunkt des Ausbürstens des verzögerten Oberflächenmörtels. Daran schließt sich die zweite Nachbehandlung an, in der Regel durch Aufsprühen eines flüssigen Nachbehandlungsmittels.
Der zweite Nachbehandlungsschritt ist entscheidend für den Frost-Tausalz-Widerstand der Betondecke. Im Rahmen eines Forschungsprojektes wurde daher untersucht, inwiefern durch eine Optimierung der zweiten Nachbehandlung der Frost-Tausalz-Widerstand von Waschbetonoberflächen erhöht werden kann, insbesondere bei Verwendung hüttensandhaltiger Zemente. Schon durch eine einmalige Nassnachbehandlung wurde eine deutlich höherer Widerstand der Waschbetons gegen Frost-Tausalz-Angriff erzielt.
Die besondere Aggressivität von hochkonzentrierten Magnesiumsulfatlösungen bei Einwirkung auf Beton ist seit vielen Jahrzehnten bekannt. Neben dem Sulfat greift zusätzlich auch das Magnesium den Zementstein an. Bei hohen Lösungskonzentrationen nimmt der Magnesiumangriff gegenüber dem Sulfatangriff sogar eine dominante Rolle ein. Magnesiumgehalte unter 300 mg/l im Grundwasser gelten allerdings bislang als nicht angreifend. In Auslagerungs- und Laborversuchen wurde jedoch festgestellt, dass auch bei praxisrelevanten Magnesium- (<300 mg/l) und Sulfatgehalten (1.500 mg/l) das Magnesium zu einer deutlichen Verschärfung des Sulfatangriffes bei niedrigen Temperaturen führte. Diese Verschärfung trat bei Mörteln und Betonen auf, bei denen der erhöhte Sulfatwiderstand durch einen teilweisen Zementersatz mit 20 % Flugasche zu einem CEM II/A-LL erreicht werden sollte, gemäß der Flugascheregelung nach EN 206-1/DIN 1045-2.
Bei einem teilweisen Zementersatz durch 30 % Flugasche konnte auch in magnesiumhaltigen Sulfatlösungen eine deutliche Verbesserung des Sulfatwiderstandes erreicht werden. Mörtel mit HS-Zement als Bindemittel wiesen keinerlei Schäden auf. Schadensverursachend war eine Kombination mehrerer Einflüsse. Zum einen wurde der Sulfatwiderstand des Zement-Flugasche-Systems durch die unzureichende Reaktion der Flugasche infolge der niedrigen Lagerungstemperatur geschwächt. Zum anderen konnte durch die Einwirkung des Magnesiums in der Randzone vermutlich eine Destabilisierung der C-S-H-Phasen erfolgen, wodurch die Thaumasitbildung an dieser Stelle forciert wurde. Zusätzlich wurde durch den Portlanditverbrauch und die pH-Wert-Absenkung in der Randzone die puzzolanische Reaktion der Flugasche behindert.
Flächenmanagement in Hochschulen. Workshop zu Handlungsansätzen hochschulinterner Flächensteuerung
(2013)
Die Publikation dokumentiert die Beiträge des Workshops „Flächenmanagement in Hochschulen“ der Bauhaus-Universität Weimar, Professur Betriebswirtschaftslehre im Bauwesen, vom 19.11.2012. Insbesondere für Akteure aus Lehre, Forschung, Hochschulverwaltung, Bau- und Liegenschaftsverwaltungen sowie Politik bieten die wiedergegebenen Vorträge theoretische und praktische Anregungen für das Vorgehen bei der Steuerung hochschulinterner Flächen.
Dokumentiert werden unterschiedliche Modi zur Steuerung der Flächenressourcen. Ziel ist es dabei, die liegenschaftspolitischen Rahmenbedingungen aufzuzeigen, von denen das Flächenmanagement abhängig ist. Mit der Auswertung einer deutschlandweiten Hochschulbefragung zum Flächenmanagement wird der Status quo hochschulinterner Flächensteuerung nachgezeichnet. Es wird zuerst ein Überblick gegeben, welche Ansätze zur Optimierung der Flächen-steuerung von Hochschulen möglich sind. Hochschulvertreter von zwei staatlichen und einer privaten Hochschule stellten praktizierte Handlungsansätze für einen ressourcenschonenden Umgang mit Flächen vor und arbeiteten die aus ihrer Sicht Erfolg versprechenden Steuerungsaspekte heraus. Zusätzliche Diskussionsimpulse für die Flächensteuerung an Hochschulen bieten die Dokumentationen von Praxisbeispielen aus anderen Bereichen. Es werden das Vorgehen bei der Flächensteuerung eines Chemie- und Pharmakonzerns mit umfangreichen eigenen Forschungsaktivitäten sowie Flächenoptimierungsmaßnahmen bei Büroflächen der öffentlichen Verwaltung vorgestellt.
Based on the description of a conceptual framework for the representation of planning problems on various scales, we introduce an evolutionary design optimization system. This system is exemplified by means of the generation of street networks with locally defined properties for centrality. We show three different scenarios for planning requirements and evaluate the resulting structures with respect to the requirements of our framework. Finally the potentials and challenges of the presented approach are discussed in detail.
The Bauhaus Summer School series provides an international forum for an exchange of methods and skills related to the interaction between different disciplines of modern engineering science.
The 2012 civil engineering course was held in August over two weeks at Bauhaus-Universität Weimar. The overall aim was the exchange
of research and modern scientific approaches in the field of model validation and simulation between well-known experts acting as lecturers
and active students. Besides these educational intentions the social and cultural component of the meeting has been in the focus. 48 graduate and doctoral students from 20 different countries and 22 lecturers from 12 countries attended this summer school. Among
other aspects, this activity can be considered successful as it raised the
sensitivity towards both the significance of research in civil engineering
and the role of intercultural exchange.
This volume summarizes and publishes some of the results: abstracts
of key note papers presented by the experts and selected student
research works. The overview reflects the quality of this summer school.
Furthermore the individual contributions confirm that for active students
this event has been a research forum and a special opportunity
to learn from the experiences of the researchers in terms of methodology
and strategies for research implementation in their current work.
Damping in Bolted Joints
(2013)
With the help of modern CAE-based simulation processes, it is possible to predict the dynamic behavior of fatigue strength problems in order to improve products of many industries, e.g. the building, the machine construction or the automotive industry. Amongst others, it can be used to improve the acoustic design of automobiles in an early development stage.
Nowadays, the acoustics of automobiles plays a crucial role in the process of vehicle development. Because of the advanced demand of comfort and due to statutory rules the manufacturers are faced with the challenge of optimizing their car’s sound emissions. The optimization includes not only the reduction of noises. Lately with the trend to hybrid and electric cars, it has been shown that vehicles can become too quiet. Thus, the prediction of structural and acoustic properties based on FE-simulations is becoming increasingly important before any experimental prototype is examined. With the state of the art, qualitative comparisons between different implementations are possible. However, an accurate and reliable quantitative prediction is still a challenge.
One aspect in the context of increasing the prediction quality of acoustic (or general oscillating) problems - especially in power-trains of automobiles - is the more accurate implementation of damping in joint structures. While material damping occurs globally and homogenous in a structural system, the damping due to joints is a very local problem, since energy is especially dissipated in the vicinity of joints.
This paper focusses on experimental and numerical studies performed on a single (extracted) screw connection. Starting with experimental studies that are used to identify the underlying physical model of the energy loss, the locally influencing parameters (e.g. the damping factor) should be identified. In contrast to similar research projects, the approach tends to a more local consideration within the joint interface. Tangential stiffness and energy loss within the interface are spatially distributed and interactions between the influencing parameters are regarded. As a result, the damping matrix is no longer proportional to mass or stiffness matrix, since it is composed of the global material damping and the local joint damping. With this new approach, the prediction quality can be increased, since the local distribution of the physical parameters within the joint interface corresponds much closer to the reality.
La ri-fondazione della Libia balbiana (1933-1939). Il poderoso racconto fotografico dei “Ventimila”
(2014)
La prima edizione di questo testo è apparsa negli atti del VI Convegno Internazionale di Studi del CIRICE – Centro Interdipartimentale di Ricerca sull’Iconografia della Città Europea − Università di Napoli Federico II, (Napoli, 13-15 marzo 2014), dal titolo: Città mediterranee in trasformazione. Identità e immagine del paesaggio urbano tra Sette e Novecento, a cura di A. Buccaro e C. de Seta (Collana: Polis, 6; Napoli: Edizioni Scientifiche Italiane, 2014; pp. 1216; ISBN 9788849528145), all’interno della sessione 7, Le trasformazioni del paesaggio urbano nella fotografia e nella cinematografia, coordinatori: F. Capano, M. Iuliano, pp. 1085-1098. Il Convegno, aperto a studiosi di ambito nazionale e internazionale, si poneva l’obiettivo di fare il punto sulla storiografia riguardante la città mediterranea in età contemporanea, con particolare riferimento alla sua identità, struttura e immagine, dall’inizio dell’industrializzazione all’età post-illuminista e borghese, fino ai temi inerenti l’evoluzione/involuzione del territorio e del paesaggio post-industriale, nonché lo sviluppo del modello turistico tra Otto e Novecento.
Reinforced concrete walls are commonly selected as the lateral resisting systems in seismic design of buildings. The design procedure requires reliable/robust models to predict the wall response. Many researchers, thus, have focused on using the available experimental data to be able to comment on the quality of models at hand. What is missing though is an uncertain attitude towards the experimental data since such data can be affected by different sources of uncertainty. In this paper, we introduce the database created for model quality evaluation purposes considering the uncertainties in the experimental data. This is the first step of a larger study on experience-based model quality evaluation of reinforced concrete walls. Here, we briefly present the database as well as six sample validations of the developed numerical model (the quality of which is to be assessed). The database contains the information on nearly 300 wall specimens from about 50 sources. Both the database and the numerical model, built for uncertainty/sensitivity analysis purposes, are mainly based on ten parameters. These include geometry, material, reinforcement layout and loading properties. The validation results prove that the model is able to predict the wall response satisfactorily. Consequently, the validated numerical model could be used in further quality evaluation studies.
One of the most promising and recent advances in computer-based planning is the transition from classical geometric modeling to building information modeling (BIM). Building information models support the representation, storage, and exchange of various information relevant to construction planning. This information can be used for describing, e.g., geometric/physical properties or costs of a building, for creating construction schedules, or for representing other characteristics of construction projects. Based on this information, plans and specifications as well as reports and presentations of a planned building can be created automatically. A fundamental principle of BIM is object parameterization, which allows specifying geometrical, numerical, algebraic and associative dependencies between objects contained in a building information model. In this paper, existing challenges of parametric modeling using the Industry Foundation Classes (IFC) as a federated model for integrated planning are shown, and open research questions are discussed.
IFC-BASED MONITORING INFORMATION MODELING FOR DATA MANAGEMENT IN STRUCTURAL HEALTH MONITORING
(2015)
This conceptual paper discusses opportunities and challenges towards the digital representation of structural health monitoring systems using the Industry Foundation Classes (IFC) standard. State-of-the-art sensor nodes, collecting structural and environmental data from civil infrastructure systems, are capable of processing and analyzing the data sets directly on-board the nodes. Structural health monitoring (SHM) based on sensor nodes that possess so called “on-chip intelligence” is, in this study, referred to as “intelligent SHM”, and the infrastructure system being equipped with an intelligent SHM system is referred to as “intelligent infrastructure”. Although intelligent SHM will continue to grow, it is not possible, on a well-defined formalism, to digitally represent information about sensors, about the overall SHM system, and about the monitoring strategies being implemented (“monitoring-related information”). Based on a review of available SHM regulations and guidelines as well as existing sensor models and sensor modeling languages, this conceptual paper investigates how to digitally represent monitoring-related information in a semantic model. With the Industry Foundation Classes, there exists an open standard for the digital representation of building information; however, it is not possible to represent monitoring-related information using the IFC object model. This paper proposes a conceptual approach for extending the current IFC object model in order to include monitoring-related information. Taking civil infrastructure systems as an illustrative example, it becomes possible to adequately represent, process, and exchange monitoring-related information throughout the whole life cycle of civil infrastructure systems, which is referred to as monitoring information modeling (MIM). However, since this paper is conceptual, additional research efforts are required to further investigate, implement, and validate the proposed concepts and methods.
Performing parameter identification prior to numerical simulation is an essential task in geotechnical engineering. However, it has to be kept in mind that the accuracy of the obtained parameter is closely related to the chosen experimental setup, such as the number of sensors as well as their location. A well considered position of sensors can increase the quality of the measurement and to reduce the number of monitoring points. This Paper illustrates this concept by means of a loading device that is used to identify the stiffness and permeability of soft clays. With an initial setup of the measurement devices the pore water pressure and the vertical displacements are recorded and used to identify the afore mentioned parameters. Starting from these identified parameters, the optimal measurement setup is investigated with a method based on global sensitivity analysis. This method shows an optimal sensor location assuming three sensors for each measured quantity, and the results are discussed.
The theory of regular quaternionic functions of a reduced quaternionic variable is a 3-dimensional generalization of complex analysis. The Moisil-Theodorescu system (MTS) is a regularity condition for such functions depending on the radius vector r = ix+jy+kz seen as a reduced quaternionic variable. The analogues of the main theorems of complex analysis for the MTS in quaternion forms are established: Cauchy, Cauchy integral formula, Taylor and Laurent series, approximation theorems and Cauchy type integral properties. The analogues of positive powers (inner spherical monogenics) are investigated: the set of recurrence formulas between the inner spherical monogenics and the explicit formulas are established. Some applications of the regular function in the elasticity theory and hydrodynamics are given.
Portugal is one of the European countries with higher spatial and population freeway network coverage. The sharp growth of this network in the last years instigates the use of methods of analysis and the evaluation of their quality of service in terms of the traffic performance, typically performed through internationally accepted methodologies, namely that presented in the Highway Capacity Manual (HCM). Lately, the use of microscopic traffic simulation models has been increasingly widespread. These models simulate the individual movement of the vehicles, allowing to perform traffic analysis. The main target of this study was to verify the possibility of using microsimulation as an auxiliary tool in the adaptation of the methodology by HCM 2000 to Portugal. For this purpose, were used the microscopic simulators AIMSUN and VISSIM for the simulation of the traffic circulation in the A5 Portuguese freeway. The results allowed the analysis of the influence of the main geometric and traffic factors involved in the methodology by HCM 2000. In conclusion, the study presents the main advantages and limitations of the microsimulators AIMSUN and VISSIM in modelling the traffic circulation in Portuguese freeways. The main limitation is that these microsimulators are not able to simulate explicitly some of the factors considered in the HCM 2000 methodology, which invalidates their direct use as a tool in the quantification of those effects and, consequently, makes the direct adaptation of this methodology to Portugal impracticable.
Urban design played a central role for the European dictatorships during the 20th century, it served to legitimate the regime, to produce agreement, to demonstrate power, efficiency and speed, it communicated the social, as well as design projects, of the dictatorial regimes domestically and internationally, it tied old experts, as well as new, to the regime. Dictatorial urban design also played an important role after the fall of the dictatorships: It became the object of structural and verbal handling strategies: of demolition, of transformation, of reconstruction, of forgetting, of suppressing, of re-interpretation and of glorification. The topic area is, therefore, both historical and relevant to the present day. The discussion of the topic area is, like it or not, always embedded in the present state of societal engagement with dictatorships.
In order to even be able to discuss all of these aspects, different conceptual decisions are necessary. In retrospect, these may seem to many as self-evident, although they are anything but. Our thesis is that there are three methodological imperatives, especially, which allow an expanded approach to the topic area “urban design and dictatorship”. First and above all, the tunnel view, focused on individual dictatorships and neglecting the international dimension, must be overcome. Second, the differences in urban design over the course of a dictatorship, through an appropriate periodisation, should be emphasised. Third, we must strive for an open, flexible, but complex concept of urban design. The main focus lies on the urban design of the most influential dictatorships of the first half of the 20th century: Soviet Union, Fascist Italy and Nazi Germany, including the urban design of the autarky periods in Portugal and Spain.
After all, urban design is not just a product of specific historic circumstances. It is a form that continues to have long-term effects, which demonstrates its usefulness and adaptability throughout this process. The urban design products undoubtedly still recall the dictatorial rule under which they were created. However, they are more than a memory space. They are also a living space of the present. They can and should be discussed with respect to their spatial and functional utility for today and tomorrow. Such a perspective is a given for the citizens of a city, but also for city marketing, having marvellous consequences. Only when we do not exclude this dimension a priori, even in academic discussions, can we do justice to the products of dictatorships.
And finally, the view of the urban design of dictatorships can and must contribute to the questioning of simplified and naive conceptions of dictatorships. With urban design in mind, we can observe how dictatorships work and how they were able to prevail. In Europe, these questions are of the highest actuality.
Sensor faults can affect the dependability and the accuracy of structural health monitoring (SHM) systems. Recent studies demonstrate that artificial neural networks can be used to detect sensor faults. In this paper, decentralized artificial neural networks (ANNs) are applied for autonomous sensor fault detection. On each sensor node of a wireless SHM system, an ANN is implemented to measure and to process structural response data. Structural response data is predicted by each sensor node based on correlations between adjacent sensor nodes and on redundancies inherent in the SHM system. Evaluating the deviations (or residuals) between measured and predicted data, sensor faults are autonomously detected by the wireless sensor nodes in a fully decentralized manner. A prototype SHM system implemented in this study, which is capable of decentralized autonomous sensor fault detection, is validated in laboratory experiments through simulated sensor faults. Several topologies and modes of operation of the embedded ANNs are investigated with respect to the dependability and the accuracy of the fault detection approach. In conclusion, the prototype SHM system is able to accurately detect sensor faults, demonstrating that neural networks, processing decentralized structural response data, facilitate autonomous fault detection, thus increasing the dependability and the accuracy of structural health monitoring systems.
In this paper, we present an empirical approach for objective and quantitative benchmarking of optimization algorithms with respect to characteristics induced by the forward calculation. Due to the professional background of the authors, this benchmarking strategy is illustrated on a selection of search methods in regard to expected characteristics of geotechnical parameter back calculation problems. Starting from brief introduction into the approach employed, a strategy for optimization algorithm benchmarking is introduced. The benchmarking utilizes statistical tests carried out on well-known test functions superposed with perturbations, both chosen to mimic objective function topologies found for geotechnical objective function topologies. Here, the moved axis parallel hyper-ellipsoid test function and the generalized Ackley test function in conjunction with an adjustable quantity of objective function topology roughness and fraction of failing forward calculations is analyzed. In total, results for 5 optimization algorithms are presented, compared and discussed.
VARIATIONAL POSITING AND SOLUTION OF COUPLED THERMOMECHANICAL PROBLEMS IN A REFERENCE CONFIGURATION
(2015)
Variational formulation of a coupled thermomechanical problem of anisotropic solids for the case of non-isothermal finite deformations in a reference configuration is shown. The formulation of the problem includes: a condition of equilibrium flow of a deformation process in the reference configuration; an equation of a coupled heat conductivity in a variational form, in which an influence of deformation characteristics of a process on the temperature field is taken into account; tensor-linear constitutive relations for a hypoelastic material; kinematic and evolutional relations; initial and boundary conditions. Based on this formulation several axisymmetric isothermal and coupled problems of finite deformations of isotropic and anisotropic bodies are solved. The solution of coupled thermomechanical problems for a hollow cylinder in case of finite deformation showed an essential influence of coupling on distribution of temperature, stresses and strains. The obtained solutions show the development of stressstrain state and temperature changing in axisymmetric bodies in the case of finite deformations.
Polymer modification of mortar and concrete is a widely used technique in order to improve their durability properties. Hitherto, the main application fields of such materials are repair and restoration of buildings. However, due to the constant increment of service life requirements and the cost efficiency, polymer modified concrete (PCC) is also used for construction purposes. Therefore, there is a demand for studying the mechanical properties of PCC and entitative differences compared to conventional concrete (CC). It is significant to investigate whether all the assumed hypotheses and existing analytical formulations about CC are also valid for PCC. In the present study, analytical models available in the literature are evaluated. These models are used for estimating mechanical properties of concrete. The investigated property in this study is the modulus of elasticity, which is estimated with respect to the value of compressive strength. One existing database was extended and adapted for polymer-modified concrete mixtures along with their experimentally measured mechanical properties. Based on the indexed data a comparison between model predictions and experiments was conducted by calculation of forecast errors.
What is nowadays called (classic) Clifford analysis consists in the establishment of a function theory for functions belonging to the kernel of the Dirac operator. While such functions can very well describe problems of a particle with internal SU(2)-symmetries, higher order symmetries are beyond this theory. Although many modifications (such as Yang-Mills theory) were suggested over the years they could not address the principal problem, the need of a n-fold factorization of the d’Alembert operator. In this paper we present the basic tools of a fractional function theory in higher dimensions, for the transport operator (alpha = 1/2 ), by means of a fractional correspondence to the Weyl relations via fractional Riemann-Liouville derivatives. A Fischer decomposition, fractional Euler and Gamma operators, monogenic projection, and basic fractional homogeneous powers are constructed.
Recently there has been a surge of interest in PDEs involving fractional derivatives in different fields of engineering. In this extended abstract we present some of the results developedin [3]. We compute the fundamental solution for the three-parameter fractional Laplace operator Δ by transforming the eigenfunction equation into an integral equation and applying the method of separation of variables. The obtained solutions are expressed in terms of Mittag-Leffer functions. For more details we refer the interested reader to [3] where it is also presented an operational approach based on the two Laplace transform.
This article presents the Rigid Finite Element Method in the calculation of reinforced concrete beam deflection with cracks. Initially, this method was used in the shipbuilding industry. Later, it was adapted in the homogeneous calculations of the bar structures. In this method, rigid mass discs serve as an element model. In the flat layout, three generalized coordinates (two translational and one rotational) correspond to each disc. These discs are connected by elastic ties. The genuine idea is to take into account a discrete crack in the Rigid Finite Element Method. It consists in the suitable reduction of the rigidity in rotational ties located in the spots, where cracks occurred. The susceptibility of this tie results from the flexural deformability of the element and the occurrence of the crack. As part of the numerical analyses, the influence of cracks on the total deflection of beams was determined. Furthermore, the results of the calculations were compared to the results of the experiment. Overestimations of the calculated deflections against the measured deflections were found. The article specifies the size of the overestimation and describes its causes.
The sizing of simple resonators like guitar strings or laser mirrors is directly connected to the wavelength and represents no complex optimisation problem. This is not the case with liquid-filled acoustic resonators of non-trivial geometries, where several masses and stiffnesses of the structure and the fluid have to fit together. This creates a scenario of many competing and interacting resonances varying in relative strength and frequency when design parameters change. Hence, the resonator design involves a parameter-tuning problem with many local optima. As its solution evolutionary algorithms (EA) coupled to a forced-harmonic FE simulation are presented. A new hybrid EA is proposed and compared to two state-of-theart EAs based on selected test problems. The motivating background is the search for better resonators suitable for sonofusion experiments where extreme states of matter are sought in collapsing cavitation bubbles.
The p-Laplace equation is a nonlinear generalization of the Laplace equation. This generalization is often used as a model problem for special types of nonlinearities. The p-Laplace equation can be seen as a bridge between very general nonlinear equations and the linear Laplace equation. The aim of this paper is to solve the p-Laplace equation for 2 < p < 3 and to find strong solutions. The idea is to apply a hypercomplex integral operator and spatial function theoretic methods to transform the p-Laplace equation into the p-Dirac equation. This equation will be solved iteratively by using a fixed point theorem.
Over the last decade, the technology of constructing buildings has been dramatically developed especially with the huge growth of CAD tools that help in modeling buildings, bridges, roads and other construction objects. Often quality control and size accuracy in the factory or on construction site are based on manual measurements of discrete points. These measured points of the realized object or a part of it will be compared with the points of the corresponding CAD model to see whether and where the construction element fits into the respective CAD model. This process is very complicated and difficult even when using modern measuring technology. This is due to the complicated shape of the components, the large amount of manually detected measured data and the high cost of manual processing of measured values. However, by using a modern 3D scanner one gets information of the whole constructed object and one can make a complete comparison against the CAD model. It gives an idea about quality of objects on the whole. In this paper, we present a case study of controlling the quality of measurement during the constructing phase of a steel bridge by using 3D point cloud technology. Preliminary results show that an early detection of mismatching between real element and CAD model could save a lot of time, efforts and obviously expenses.
The stress state of a piecewise-homogeneous elastic body, which has a semi-infinite crack along the interface, under in-plane and antiplane loads is considered. One of the crack edges is reinforced by a rigid patch plate on a finite interval adjacent to the crack tip. The crack edges are loaded with specified stresses. The body is stretched at infinity by specified stresses. External forces with a given principal vector and moment act on the patch plate. The problem reduces to a Riemann-Hilbert boundary-value matrix problem with a piecewise-constant coefficient for two complex potentials in the plane case and for one in the antiplane case. The complex potentials are found explicitly using a Gaussian hypergeometric function. The stress state of the body close to the ends of the patch plate, one of which is also simultaneously the crack tip, is investigated. Stress intensity factors near the singular points are determined.
Steel profiles with slender cross-sections are characterized by their high susceptibility to instability phenomena, especially local buckling, which are intensified under fire conditions. This work presents a study on numerical modelling of the behaviour of steel structural elements in case of fire with slender cross-sections. To accurately carry out these analyses it is necessary to take into account those local instability modes, which normally is only possible with shell finite elements. However, aiming at the development of more expeditious methods, particularly important for analysing complete structures in case of fire, recent studies have proposed the use of beam finite elements considering the presence of local buckling through the implementation of a new effective steel constitutive law. The objective of this work is to develop a study to validate this methodology using the program SAFIR. Comparisons are made between the results obtained applying the referred new methodology and finite element analyses using shell elements. The studies were made to laterally restrained beams, unrestrained beams, axially compressed columns and columns subjected to bending plus compression.
In photogrammetry and computer vision the trifocal tensor is used to describe the geometric relation between projections of points in three views. In this paper we analyze the stability and accuracy of the metric trifocal tensor for calibrated cameras. Since a minimal parameterization of the metric trifocal tensor is challenging, the additional constraints of the interior orientation are applied to the well-known projective 6-point and 7-point algorithms for three images. The experimental results show that the linear 7-point algorithm fails for some noise-free degenerated cases, whereas the minimal 6-point algorithm seems to be competitive even with realistic noise.
The Laguerre polynomials appear naturally in many branches of pure and applied mathematics and mathematical physics. Debnath introduced the Laguerre transform and derived some of its properties. He also discussed the applications in study of heat conduction and to the oscillations of a very long and heavy chain with variable tension. An explicit boundedness for some class of Laguerre integral transforms will be present.
SELECTION AND SCALING OF GROUND MOTION RECORDS FOR SEISMIC ANALYSIS USING AN OPTIMIZATION ALGORITHM
(2015)
The nonlinear time history analysis and seismic performance based methods require a set of scaled ground motions. The conventional procedure of ground motion selection is based on matching the motion properties, e.g. magnitude, amplitude, fault distance, and fault mechanism. The seismic target spectrum is only used in the scaling process following the random selection process. Therefore, the aim of the paper is to present a procedure to select a sets of ground motions from a built database of ground motions. The selection procedure is based on running an optimization problem using Dijkstra’s algorithm to match the selected set of ground motions to a target response spectrum. The selection and scaling procedure of optimized sets of ground motions is presented by examining the analyses of nonlinear single degree of freedom systems.